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paddlepaddle--paddle/test/auto_parallel/pir/test_to_static_pir_program.py
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2026-07-13 12:40:42 +08:00

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9.5 KiB
Python

# Copyright (c) 2024 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import unittest
import numpy as np
import paddle
import paddle.distributed as dist
from paddle import nn
from paddle.distributed import Replicate, Shard
from paddle.io import DataLoader
BATCH_SIZE = 4
BATCH_NUM = 40
IMAGE_SIZE = 16
CLASS_NUM = 8
np.random.seed(2024)
paddle.seed(2024)
class RandomDataset(paddle.io.Dataset):
def __init__(self, images, labels, num_samples):
self.images = images
self.labels = labels
self.num_samples = num_samples
def __getitem__(self, idx):
return self.images[idx], self.labels[idx]
def __len__(self):
return self.num_samples
class DemoNet(nn.Layer):
def __init__(self, mesh, shard=True):
super().__init__()
self._mesh = mesh
self.linear_0 = nn.Linear(IMAGE_SIZE, IMAGE_SIZE, bias_attr=False)
self.linear_1 = nn.Linear(IMAGE_SIZE, CLASS_NUM, bias_attr=False)
self.relu_0 = nn.ReLU()
self.relu_1 = nn.ReLU()
self.relu_2 = nn.ReLU()
self.shard = shard
# shard the weights of this layer
if self.shard:
self.linear_0.weight = dist.shard_tensor(
self.linear_0.weight,
self._mesh,
[Shard(1)],
stop_gradient=False,
)
self.linear_1.weight = dist.shard_tensor(
self.linear_1.weight,
self._mesh,
[Shard(0)],
stop_gradient=False,
)
else:
self.linear_0.weight = dist.shard_tensor(
self.linear_0.weight,
self._mesh,
[Replicate()],
stop_gradient=False,
)
self.linear_1.weight = dist.shard_tensor(
self.linear_1.weight,
self._mesh,
[Replicate()],
stop_gradient=False,
)
def forward(self, x):
x.stop_gradient = False
out = self.relu_0(x) # triggle backward partial allreduce
out = self.linear_0(out)
out = self.relu_1(out)
out = self.linear_1(out)
out = self.relu_2(out) # triggle forward partial allreduce
out = paddle.cast(out, 'float32')
return out
def create_data_loader(
batch_size=BATCH_SIZE,
batch_num=BATCH_NUM,
image_size=IMAGE_SIZE,
class_num=CLASS_NUM,
):
nsamples = batch_size * batch_num
images = np.random.rand(nsamples, image_size).astype('float32')
labels = np.random.rand(nsamples, class_num).astype('float32')
dataset = RandomDataset(images, labels, nsamples)
loader = DataLoader(dataset, batch_size=batch_size)
return loader
class TestToStaticPirProgramTrain(unittest.TestCase):
def test_to_static_program(self):
paddle.base.set_flags({'FLAGS_enable_pir_api': 1})
mesh = dist.ProcessMesh([0, 1], dim_names=["x"])
layer = DemoNet(mesh)
opt = paddle.optimizer.SGD(
learning_rate=0.1, parameters=layer.parameters()
)
loss_fn = nn.MSELoss()
loader = create_data_loader()
dist_loader = dist.shard_dataloader(loader, meshes=[mesh])
dist_model = dist.to_static(layer, dist_loader, loss_fn, opt)
# dist_model.train()
mode = "train"
dist_model.train()
main_program = dist_model._engine._pir_dist_main_progs["train"]
relu_idx = 0
matmul_idx = 0
data_idx = 0
matmul_grad_idx = 0
sgd_idx = 0
ops = main_program.global_block().ops
backward_op_list = [
"pd_op.sgd_",
"pd_op.sgd_",
"pd_op.relu_grad",
"pd_op.all_reduce",
"pd_op.matmul_grad",
"pd_op.relu_grad",
"pd_op.matmul_grad",
"pd_op.relu_grad",
"pd_op.cast",
"pd_op.subtract_grad",
"pd_op.square_grad",
"pd_op.mean_grad",
]
index = -1
for op_name in backward_op_list:
self.assertEqual(ops[index].name(), op_name)
index = index - 1
for op in ops:
# skip shadow_output
if op.num_results() == 0:
continue
tensor = op.result(0)
# while tensor's stop_gradient is true, the corresponding grad tensor is initialized.
if not tensor.initialized():
continue
self.assertTrue(tensor.is_dist_dense_tensor_type())
self.assertEqual(tensor.dist_attr().process_mesh.shape, [2])
self.assertEqual(
tensor.dist_attr().process_mesh.process_ids, [0, 1]
)
if op.name() == 'pd_op.data':
if data_idx != 0:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, -1])
self.assertEqual(tensor.dist_attr().partial_dims, set())
data_idx += 1
elif op.name() == 'builtin.parameter':
self.assertTrue(tensor.is_dense_tensor_type())
self.assertTrue(tensor.is_dist_dense_tensor_type())
self.assertTrue(tensor.is_dist_dense_tensor_type())
self.assertEqual(tensor.dist_attr().process_mesh.shape, [2])
self.assertEqual(
tensor.dist_attr().process_mesh.process_ids, [0, 1]
)
if tensor.shape == [IMAGE_SIZE, IMAGE_SIZE]:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, 0])
elif tensor.shape == [IMAGE_SIZE, CLASS_NUM]:
self.assertEqual(tensor.dist_attr().dims_mapping, [0, -1])
self.assertEqual(tensor.dist_attr().partial_dims, set())
if op.name() == 'pd_op.relu':
if relu_idx == 0:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, -1])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, IMAGE_SIZE]
)
elif relu_idx == 1:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, 0])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, IMAGE_SIZE // 2]
)
elif relu_idx == 2:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, -1])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, CLASS_NUM]
)
relu_idx += 1
if op.name() == 'pd_op.matmul':
if matmul_idx == 0:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, 0])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, IMAGE_SIZE // 2]
)
elif matmul_idx == 1:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, -1])
self.assertEqual(tensor.dist_attr().partial_dims, {0})
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, CLASS_NUM]
)
matmul_idx += 1
if op.name() == 'pd_op.matmul_grad':
if matmul_grad_idx == 0:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, 0])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, CLASS_NUM]
)
elif matmul_grad_idx == 1:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, -1])
self.assertEqual(tensor.dist_attr().partial_dims, {0})
self.assertEqual(
tensor._local_shape, [BATCH_SIZE, IMAGE_SIZE]
)
matmul_grad_idx += 1
if op.name() == 'pd_op.sgd_':
if sgd_idx == 0:
self.assertEqual(tensor.dist_attr().dims_mapping, [0, -1])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [IMAGE_SIZE // 2, CLASS_NUM]
)
elif sgd_idx == 1:
self.assertEqual(tensor.dist_attr().dims_mapping, [-1, 0])
self.assertEqual(tensor.dist_attr().partial_dims, set())
self.assertEqual(
tensor._local_shape, [IMAGE_SIZE, IMAGE_SIZE // 2]
)
sgd_idx += 1
# dist_model.train()
# for batch_id, (image, label) in enumerate(dist_loader()):
# loss = dist_model(image, label)
if __name__ == "__main__":
unittest.main()